KR102180964B1 - Smart healthcare system and method for decomposing body fat based on metabolism monitoring - Google Patents

Abstract

The present invention measures metabolism and detects metabolism such as subcutaneous fat thickness, body composition, and fat cell size for each body part where visceral fat and abdominal subcutaneous fat are located, and then the body part according to the subcutaneous fat thickness and the amount of metabolic change. Body fat decomposition based on metabolic monitoring that significantly improves the efficiency of fat reduction by selectively decomposing visceral fat and abdominal subcutaneous fat by irradiating by varying the intensity and wavelength of the body fat decomposition light source of different wavelengths and intensities for each It provides a device, a wearing device for decomposing body fat, and a method thereof.

Description

A smart healthcare system and method for decomposing body fat based on metabolic monitoring {SMART HEALTHCARE SYSTEM AND METHOD FOR DECOMPOSING BODY FAT BASED ON METABOLISM MONITORING}

The present invention relates to a technology and monitoring of body fat reduction using light that decomposes body fat, and more particularly, by measuring the thickness and metabolism of the abdominal subcutaneous fat using light in the NIR-VIS (Near Infrared-Visible) band. Afterwards, by irradiating body fat decomposition light of different wavelength and intensity according to the thickness of the subcutaneous fat and metabolism, decomposing body fat, and measuring the thickness of the subcutaneous fat and metabolism again while decomposing the body fat and calculating the change thereof. It relates to a smart healthcare system and method for decomposing body fat based on metabolic monitoring that efficiently removes fat and abdominal subcutaneous fat.

In addition, the present invention transmits the measured metabolic data to a cloud server through a mobile app to analyze the individual's health condition based on big data, and sets the treatment laser wavelength, power and irradiation time of the wearable device according to the analysis result. , It relates to a smart healthcare system and method for body fat decomposition based on metabolic monitoring, which makes continuous personal health information management database and provides various personalized information such as exercise, target amount, and healthy diet suitable for the current state.

In addition, the present invention is a technology that can obtain various benefits such as a given product through data mining as everyone achieves the goal by setting a number of common goals grouped by combining smart healthcare platform and blockchain technology. By providing a way to inspire motivation and enjoyment of health care by providing benefits for the majority of people to work together to achieve goals for health management such as diet, and achieve common goals, ultimately aging. The present invention relates to a smart healthcare system and method for metabolic monitoring-based body fat decomposition that can reduce social costs required for managing chronic diseases that increase with social entry.

Obesity is an important factor that increases the risk of developing high blood pressure, cerebral hemorrhage, heart disease, shortness of breath, and cancer. With industrialization, the number of obese population is increasing worldwide. Accordingly, many people perform various exercises for the prevention or treatment of obesity, but when exercise time is not available, efforts to decompose body fat by ingesting supplements or wearing auxiliary devices are being conducted in parallel.

As an example of such an auxiliary device for body fat removal, exercise by promoting the decomposition of body fat decomposed by the light source by applying vibration while irradiating a light source for decomposing body fat in Korean Patent No. 10-1744195 Disclosed is a wearable device for removing body fat that allows body fat to be removed by simply wearing it without performing it.

However, in the case of the above-described conventional technology, two light sources having different wavelengths are arranged and used, and the user's body fat can be measured, but the operation of the device or the intensity of light is adjusted by reflecting the measured body fat information. Since there is no function such as to do so, users with thick subcutaneous fat have a problem that the light does not reach deep subcutaneous fat or visceral fat. In addition, even if management of visceral fat rather than subcutaneous fat is necessary, adjustment is not possible.

According to a recent study, it has been reported that the intensity of uncontrolled light increases the metabolism of the human body, thereby reducing visceral fat, but in the case of abdominal subcutaneous fat, it may cause problems such as increasing it.

In other words, the wavelengths of light sources mainly used in low-level laser therapy (LLLT) are 635nm and 830nm, and by irradiating low-power light, it improves circulation, improves metabolism, and dilates blood vessels along with a thermal effect. Pain or wound treatment is performed, and at this time, the thickness of the abdominal subcutaneous fat increases through the activation of collagen in the subcutaneous fat.

In addition, with the entry of an aging society, social costs are increasing for the management and treatment of various chronic diseases, and as interest in reducing them increases, various mobile healthcare devices (eg. Apple Watch, Samsung Gear, Fitbut, Nike Fuel, etc.) ) Is being released. Contrary to expectations, however, a commercial imitation day healthcare device simply monitors the wearer's activity against the price (activity trackint), and does not provide medical-level health information, so complaints are raised that it is impossible to use an expensive pedometer. It is becoming. Therefore, in the aging era, there is a need for a new type of health care device capable of practically personalized health management by improving the quality of life and providing medical-level health information. There is an unmet needs for a new type of health care platform that can provide enjoyment and constant motivation to individuals for continuous health management.

Korean Patent Registration No. 10-1744195

The present invention is to solve the problems of the prior art described above, using a multi-distance diffused light spectroscopy to measure the thickness and metabolism of subcutaneous fat by body part, and a light source for body fat decomposition according to the goal of reducing subcutaneous fat or visceral fat Metabolic monitoring-based body fat decomposition wear device that enables efficient removal of visceral fat and abdominal subcutaneous fat by varying the intensity, wavelength, and irradiation time of the body, and personalized health through cloud service using this The purpose of this is to provide a smart healthcare system and method for decomposing body fat based on metabolic monitoring that can be managed.

In addition, the present invention is not a record of simple activities, but physiological information of the human body, that is, the amount of oxygen-bound hemoglobin (HbO2), the amount of unbound hemoglobin (HbR), body moisture, lipids, etc. Measurement data can be provided and transmitted to a cloud server to enable more professional personalized health management through big data analysis, as well as people with a common goal connected to the smart healthcare platform. It aims to provide a smart healthcare system and method for body fat decomposition based on metabolic monitoring that can provide a function that can induce steady health management through motivation as well as the pleasure of achieving the goal.

A smart healthcare system for decomposing body fat based on metabolic monitoring of the present invention for achieving the above object,

The body fat decomposition device (1) based on metabolic monitoring is connected to each other, and is composed of a plurality of sections and is configured to be wearable, and the metabolic measurement data that monitors the metabolism of the wearer in the worn state is generated, and the metabolism Metabolic monitoring-based body fat decomposition wearing device (p) for decomposing body fat by emitting light to the wearer's body odor side according to the measurement data;

A terminal 10 capable of transmitting and receiving data with the wearing device p for decomposing body fat, receiving the metabolic measurement data, and transmitting the wearing device setting and control information;

Receives the metabolic measurement data from the terminal 10, operates a block compensation system using big data analysis and blockchain technology according to the metabolic measurement data, and generates personalized data according to the operation, and the terminal 10 A cloud server that transmits to); It may be configured to include. The body fat decomposition apparatus 1,

After irradiating light for measuring the thickness of subcutaneous fat and multi-wavelength body composition to monitor metabolism through the body composition measurement light source unit 110, the diffused light diffused while passing through the internal tissues is transferred to the light detection unit 120. A body composition measuring unit 100 that detects and outputs a thickness and body composition measurement signal of subcutaneous fat;

Body fat decomposition light source 200 for emitting light for decomposing body fat;

Body fat decomposition light power control unit 400 for outputting multi-wavelength light source driving power for outputting the body fat decomposition light of individual body fat decomposition multi-wavelength light sources 210 according to the body fat decomposition light control signal input from the control unit 500;

A body fat decomposition signal switching unit 300 for transmitting power to the multi-wavelength light source driving power output from the body fat decomposition light power control unit 400 to each of the body fat decomposition multi-wavelength light sources 210;

The body composition measurement light source unit 110 of the body composition measurement unit 100 outputs a body composition measurement light control signal that adjusts the output wavelength and intensity of the body composition measurement light, and the light detection unit 120 of the body composition measurement unit 100 After performing the analysis of the thickness and body composition of the subcutaneous fat using the diffused light signal received by, the metabolism measurement data generated by generating metabolic specific data is controlled to be transmitted to the terminal 10, and the metabolism A control unit 500 for adjusting the intensity and irradiation time of each wavelength of the body fat decomposition light source unit 200 by receiving a set value for adjusting the body fat decomposition light source received according to the result of analysis based on big data according to the measurement data;

A power supply unit 600 for supplying power required for the body fat decomposing device 1 and charging a battery;

A communication unit 700 for transmitting the metabolic measurement data from the control unit 500 to the terminal 10; And

When the body fat decomposing devices 1 are configured into a plurality of sections, a connector 800 required for connection may be included.

The metabolic monitoring-based body fat decomposition wearing device (p),

The metabolic monitoring-based body fat decomposition device 1 may be connected to each other to be composed of a plurality of sections, the section configuration form may be varied according to the body part, and the metabolic monitoring-based body fat decomposition device 1 It is connected to both ends of (p), it may be configured to include a belt (b) coupled to be worn on the waist or body part.

An application is installed in the terminal 10, and the application,

It is installed on a computer or a portable device, and transmits the metabolic measurement data received from the wearing device (p) for decomposing body fat based on metabolism monitoring to the cloud server, and analyzes the individual's metabolism based on big data in the cloud server. Receives information such as the body fat decomposition light source control setting value, personalized exercise coaching, diet, etc., transmitted according to the health status, and shows it through the computer or portable device, and the information of the group connected through the blockchain and the common goal and It may be configured to show the degree of achievement being transmitted through the cloud server.

The body composition measuring unit 100,

A body composition measurement light source unit 110 comprising a multi-wavelength diode array light source chip that outputs body composition measurement lights having respective wavelengths and intensities;

An optical driver unit 140 for outputting a multi-wavelength light source driving power to respective diodes of a multi-wavelength diode array light source chip constituting the body composition measurement light source unit 110;

A measurement light source switching unit 150 for switching the multi-wavelength light source driving power to be input to respective diodes of the multi-wavelength diode array light source chip;

In order to add a modulated signal to the multi-wavelength light source driving power, a modulated signal of a specific frequency is output to the optical driver unit 140, and a body composition measurement signal output through the light detection unit 120 and the body composition measurement signal amplification unit 160 A filtering and amplifying unit 130 outputting the strength of the body composition measurement signal to the control unit 500 after removing noise so as to detect only a signal matching the modulated signal frequency in

The light detection unit 120 including a plurality of optical sensors spaced apart from the body composition measurement light source unit 110 at predetermined intervals to detect the diffused light emitted while passing through the internal tissues of the body and output as the body composition measurement signal ;

A body composition measurement signal amplification unit 160 for amplifying and outputting the body composition measurement signal output from the light detection unit 120; And

And a body composition measurement signal switching unit 170 for outputting the body composition measurement signals output from the body composition measurement signal amplifying unit 160 to the filtering and amplifying unit 130.

The metabolic measurement data,

Fat layer thickness for each part of the body, oxygen-bound hemoglobin (HbO2), oxygen-unbound hemoglobin (HbR), body water, Fat %, change in size of fat cells, and the relationship between each measured component and BMI (Body Mass Index) It may be configured to include one or more of R values.

The body fat decomposition light source unit 200,

Light of 635~680nm wavelength to promote absorption by activating lipolysis, light of 920~930nm wavelength to alleviate cellulite, light of 930~980nm wavelength absorbed a lot from fat and water, 805~830nm to reduce skin aging It includes an array of body fat decomposition multi-wavelength light sources 210 that can be configured to irradiate light of a wavelength by selecting a wavelength or the number of wavelengths according to a function,

The control unit 500 drives a multi-wavelength light source output from the body fat decomposition light power control unit 400 according to the body fat decomposition light control set value generated through big data analysis according to the fat layer thickness and metabolic information for each body part The body fat decomposition light source unit 200 may be configured to irradiate light having different intensities and irradiation times according to wavelengths by power.

The control unit 500

Light for body composition measurement is irradiated on the body part subject to fat decomposition,

The diffused light diffused from the internal tissue of the body fat decomposition target body part is controlled to be converted to a body composition measurement signal and output after performing multi-distance diffused light detection for each location,

Analyzing the body composition measurement signal to calculate the subcutaneous fat thickness for each body part,

The body composition measurement signal is applied to the diffuse light spectroscopy to calculate the absorption coefficient and the scattering coefficient,

Using the calculated absorption coefficient, body composition analysis information including the amount of oxygen-bound hemoglobin (HbO2), the amount of oxygen-unbound hemoglobin (HbR), the amount of body water, and the amount of lipid is generated,

The size of adipocytes is calculated using the calculated scattering coefficient,

Using the calculated subcutaneous fat thickness and fat cell size information, the obesity level (Fat %) and R value were calculated to analyze the obesity level, and metabolic measurement data according to the analyzed result was generated,

It may be configured to transmit the measured metabolic measurement data to the cloud server 20.

A smart healthcare method for decomposing body fat based on metabolic monitoring of the present invention for achieving the above object,

Generating initial metabolic measurement data by irradiating light for measuring body composition at multiple wavelengths for metabolism monitoring on a part of the body and detecting diffused light that has been diffused while passing through internal tissues at multiple distances;

Decomposing body fat by irradiating the body fat decomposition light according to the wavelength of the body fat decomposition light and the light intensity and the irradiation time to the wearer's body using the metabolic monitoring database;

It may be configured to include a; transmitting step of transmitting the metabolism measurement data generated by monitoring the metabolism again to the terminal 10.

The metabolic monitoring database may be obtained to include information on a wavelength, intensity, and irradiation time respectively set according to a set value for adjusting a light source for body fat decomposition.

After the transmission step of transmitting the metabolic measurement data to the terminal 10, the cloud server 20 receiving the metabolic measurement data from the terminal 10;

The cloud server 20 includes steps of generating personalized data including diagnosis, exercise coaching, and diet information through big data analysis of metabolic measurement data;

Changing a setting value for adjusting the body fat decomposition light source according to the creation of the personalized data;

Transmitting the changed body fat decomposition light source adjustment setting value and big data analysis data to the terminal 10;

The terminal may include a display step of displaying the changed body fat decomposition light source adjustment setting value and big data analysis data.

In the display step, the body fat decomposition light source control setting value, personalized exercise coaching, and diet information transmitted according to the individual's health condition analyzed based on big data are received and shared with information of a group connected through a block chain. It may be configured to show the target and the degree of achievement being transmitted through the cloud server.

After the step of transmitting the metabolic measurement data to the cloud server,

The cloud server, the step of receiving metabolic measurement data of the individual from the mobile app;

Converting the received individual metabolism measurement data into a database;

Analyzing the database to analyze the body fat decomposition light source adjustment setting value, personalized exercise coaching, and diet suitable for an individual, and transmitting it to the terminal 10; And

Setting an individual's health goal and applying a block compensation system using block chain technology through the mobile app when the metabolic measurement data transmitted thereafter achieves the set health goal;

Setting a common goal by grouping people with similar health level information according to a predetermined number of people through the block compensation system; female,

When the set common goal is achieved, providing a reward benefit according to the level of health achievement of each individual and an opportunity to participate in a block group consisting of a larger number of people as a next step of the block compensation system.

The present invention of the above-described configuration, in the case of reducing body fat by irradiating body fat decomposition light, measures metabolism such as the thickness of subcutaneous fat, body composition, and size of fat cells for each body part where visceral fat and abdominal subcutaneous fat are located. After detecting the metabolic rate, it is possible to selectively and efficiently decompose visceral fat and abdominal subcutaneous fat by irradiating the body fat decomposition light of different wavelength and intensity for each body part according to the subcutaneous fat thickness and the calculated metabolic rate. This provides the effect of remarkably improving the efficiency of fat reduction.

In addition, the smart healthcare platform based on medical-level measurement data enables personalized health management, and through the incorporation of blockchain technology, multiple platform users set common goals and enjoy the joy of achieving them together. By providing it, it will provide an effect of inspiring motivation for consistent health care without giving up.

1 is a block diagram of a metabolic monitoring-based body fat decomposition apparatus 1 according to an embodiment of the present invention.
2 is a functional block diagram including a circuit function of the metabolic monitoring-based body fat decomposition apparatus 1 of FIG. 1.
3 is a view showing a body fat decomposition wearing device (p) manufactured to be worn on a waist after the metabolic monitoring-based body fat decomposition apparatus 1 of FIG. 1 is configured into a plurality of sections.
4 is a graph showing the relationship between the intensity of light for decomposing body fat and the pulse width of light.
5 is a configuration diagram showing the configuration and data flow of the wearing device for body fat decomposition based on metabolic monitoring of the present invention and a smart healthcare platform using the same.
6 is a flow chart illustrating a process of processing mutual data between a wearing device for body fat decomposition based on metabolic monitoring, a mobile app, and a cloud server according to an embodiment of the present invention.
7 is a flowchart illustrating a process of performing block compensation in a cloud server according to an embodiment of the present invention.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Since the embodiments according to the concept of the present invention can be changed in various ways and have various forms, specific embodiments will be illustrated in the drawings and described in detail in the present specification or application. However, this is not intended to limit the embodiments according to the concept of the present invention to a specific form of disclosure, and the present invention should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention. In addition, the word "exemplary" in this specification is used to mean "to serve as an example, as an example, or as an illustration." Any aspects described herein as “exemplary” are not necessarily to be construed as preferred or advantageous over other aspects.

When a component is referred to as being "connected" or "connected" to another component, it is understood that it may be directly connected or connected to the other component, but other components may exist in the middle. Should be. On the other hand, when a component is referred to as being "directly connected" or "directly connected" to another component, it should be understood that there is no other component in the middle. Other expressions describing the relationship between components, such as "between" and "just between" or "adjacent to" and "directly adjacent to" should be interpreted as well.

The terms used in the present specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present specification, terms such as "comprise" or "have" are intended to designate the presence of a set feature, number, step, action, component, part, or combination thereof, but one or more other features or numbers It is to be understood that the possibility of addition or presence of, steps, actions, components, parts, or combinations thereof is not preliminarily excluded.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings showing embodiments of the present invention.

1 is a block diagram of a metabolic monitoring-based body fat decomposing apparatus 1 according to an embodiment of the present invention, and FIG. 2 is a functional block diagram including a circuit function of the body fat decomposing apparatus 1, and a control unit 500 Including and additionally may be configured to further include a short-range wireless communication unit 700, the power supply unit 600, the body fat decomposition optical power control unit 400.

As shown in Figure 1, the metabolic monitoring-based body fat decomposition device 1 (hereinafter referred to as'body fat decomposition device 1') is largely used for body fat decomposition of the body composition measurement unit 100 and the body fat decomposition light source unit 200 It may be configured to include the multi-wavelength light sources 210 and the connection connector 800 required for configuration with a plurality of sections.

2, the body composition measurement unit 100 includes a filtering and amplification unit 130, an optical driver unit 140, a measurement light source switching unit 150, a body composition measurement light source unit 110, a light detection unit 120, and It includes a body composition measurement signal amplifying unit 160, and after irradiating multi-wavelength body composition measurement light for metabolism monitoring on a part of the body through the body composition measurement light source unit 110, diffused while passing through the internal tissues It is configured to perform a function of detecting light and outputting a body composition measurement signal.

The filtering and amplification unit 130 outputs a modulated signal of a specific frequency according to the body composition measurement start signal applied from the control unit 500 and transmits it to the optical driver unit 140, and is detected by the photodetector 120 to obtain a body composition. After receiving the body composition measurement signal amplified through the measurement signal amplification unit 160, it is configured to select only a signal equal to the modulation frequency, remove noise, amplify, and output to the control unit 500. The filtering and amplifying unit 130 performing the above-described functions may be configured with a lock-in amplifier or the like.

The optical driver unit 140 includes respective diodes of a multi-wavelength diode array light source constituting the body composition measurement light source unit 110 according to the body composition measurement light control signal input by the filtering and amplification unit 110. It is configured to output wavelength diode driving power sources.

The measurement light source switching unit 150 is configured to perform switching so that a plurality of multi-wavelength diode driving power inputs from the optical driver unit 140 are applied to target diodes. The measurement light source switching unit 150 having the above-described configuration may be configured as a switch including a multiplexer (MUX) or a switch element such as a plurality of transistors.

The body composition measurement light source unit 110 includes a multi-wavelength diode array light source that outputs body composition measurement lights having a wavelength and intensity selected according to the multi-wavelength diode driving power supplies. At this time, the body composition measurement light output through the multi-wavelength diode array light source includes light for each wavelength of a NIR-VIS (Near Infrared-Visible) band.

The multi-wavelength diode array light source chip that outputs multi-wavelength light as described above includes a plurality of multi-wavelength diodes including FP (Fabry-Perot), VCSEL (Vertical Cavity Surface Emitting Laser), DFB (Distributed Feedback), and LED type diodes. It may be configured by packaging to emit light, and a light source for each wavelength in the form of a die such as a VCSEL (Vertical Cavity Surface Emitting Laser) or an LED may be configured as a surface-mounted packaging chip.

The photodetector 120 is a plurality of optical sensors spaced apart from the body composition measurement light source unit 110 at predetermined intervals so as to detect diffused light that has been irradiated from the body composition measurement light source unit 110 and diffused while passing through the internal tissues, converts it into a body composition measurement signal, and outputs it. It is configured to include (121, 122, 123).

The body composition measurement signal amplification unit 160 is composed of amplifiers that amplify the body composition measurement signal output from the light detection unit 120 and output to the body composition measurement signal switching unit 170.

The body fat decomposition light power control unit 400 is configured to output multi-wavelength light source driving power for outputting the body fat decomposition light of the body fat decomposition light source unit 200 according to the body fat decomposition light control signal input from the control unit 500. . The multi-wavelength light source driving power supplies are output to the body fat decomposition multi-wavelength light sources 210 through the body fat decomposition signal switching unit 300.

The body fat decomposition light source unit 200 is composed of an array of body fat decomposition multi-wavelength light sources 210, and when the body fat decomposition apparatus 1 is composed of a plurality of sections, the multi-wavelength light source driving power supply unit is used as a body fat decomposition light source unit ( 200) By selectively outputting each body part, it is configured to irradiate body fat decomposition lights having different wavelengths and intensities. Specifically, the body fat decomposition light source 200 is light with a wavelength of 635 to 680 nm to promote absorption by activating fat decomposition, light with a wavelength of 920 to 930 nm to alleviate cellulite, and 930 to 980 nm that is highly absorbed in fat and water. It includes an array of body fat decomposition multi-wavelength light sources 210 that can be configured to irradiate light of wavelength and light of 805 to 830 nm wavelength to reduce skin aging by selecting a wavelength or number of wavelengths according to functions. The body fat decomposition light source unit 200 having the above-described configuration is the body fat decomposition light power control unit 400 according to the body fat decomposition light control signal generated by the control unit 500 for each body part according to the fat layer thickness and metabolic information for each body part. The body fat decomposition light source units 200 are configured to irradiate light having different wavelengths, intensities, and irradiation times for each body part by the multi-wavelength light source driving power outputs.

The body fat decomposition light source unit 200 may also be configured by packaging a FP (Fabry-Perot), VCSEL (Vertical Cavity Surface Emitting Laser), DFB (Distributed Feedback), and LED-type diodes to emit multiple wavelengths. In addition, a light source for each wavelength in a die form, such as a VCSEL (Vertical Cavity Surface Emitting Laser) or LED, may be configured as a surface-mounted packaging chip.

The body composition measurement light source unit 110 and the body fat decomposition light source unit 200 are configured to selectively output multi-wavelength light having a plurality of wavelengths and different intensities.

In order to control the metabolism measurement using the body composition measurement unit 100 and the body fat decomposition performed by the body fat decomposition light source unit 200, the body composition measurement light source unit of the body composition measurement unit 100 ( 110) outputs an optical control signal for body composition measurement that controls the output wavelength and intensity of the body composition measurement light, and after performing body composition analysis using the body composition measurement signal received from the body composition measurement unit 100, metabolic measurement data And the body fat decomposition optical control signals that control the wavelength and intensity of the body fat decomposition multi-wavelength light sources 310 constituting the body fat decomposition light source unit 200 according to the generated metabolic measurement data. It is configured to output to the control unit 400.

Here, the light control signal for body fat decomposition is light with a wavelength of 635 to 680 nm that promotes absorption of visceral fat depending on the thickness of body fat and the size of fat cells in the abdominal subcutaneous fat, and is absorbed by the abdominal subcutaneous fat to activate fat decomposition. It is a signal to output light with a wavelength of 920 to 930 nm that promotes the body part with a size suitable for fat decomposition.

In addition, the metabolic measurement data includes subcutaneous fat thickness, fat cell size, oxygen-bound hemoglobin (HbO2), oxygen-unbound hemoglobin (HbR), body water, lipid, Fat %, and R values. Contains one or more.

3 is a view showing a body fat decomposition wearing device p manufactured to be worn on a waist after the body fat decomposing apparatus 1 of FIG. 1 is configured into a plurality of sections.

As shown in FIG. 3, when the body fat decomposing apparatus 1 of the present invention removes body fat by irradiating a light source, the light source irradiated by detecting the subcutaneous fat thickness and the size of fat cells for each body part, and monitoring metabolic changes In order to efficiently remove visceral fat and abdominal subcutaneous fat by irradiating the intensity and wavelength of visceral fat or abdominal subcutaneous fat, the pads (p ) And a belt (b) connected to both ends of the metabolic monitoring body fat decomposing device 1 and coupled to be worn on a waist.

4 is a graph showing the relationship between the intensity of light for decomposing body fat and the pulse width of light. When the intensity of light for body fat decomposition is described with reference to FIG. 4, FIG. 4(a) continuously outputs low intensity light, and FIG. 4(b) shows higher intensity light in pulse form for T time. The output is repeated for a short time as much as tp1 time, and FIG. 4(c) is a graph showing outputting light of a higher intensity while outputting light for a shorter time than the pulse of FIG. 7(b). For example, when the thickness of the subcutaneous fat is thin and the decomposition of the subcutaneous fat is performed, it is recommended to output the light for decomposing body fat in the form of Fig. 4(a), and the thicker the thickness of the subcutaneous fat or the decomposition of visceral fat In the case of performing, outputting the body fat decomposition light in the form of (c) of FIG. 4 so that the light reaches the depth has a good effect. If the pulse width of the body fat decomposition light is narrowed, the light of high intensity is output and the light reaches the deep part of the abdomen, and the average light intensity can be maintained as shown in Fig. 4(a), thus reducing the risk due to the high intensity of light. Can be eliminated.

5 is a block diagram of a smart healthcare system capable of providing a more professional personalized health management function based on metabolic information measured through a body fat decomposition wear device.

The configuration of the system includes a body fat decomposition wearing device (p), a terminal 10 and a cloud server 20.

In detail, in the system of the present invention, the physiological information measured through the body composition measuring unit 100 of the wearing device for decomposing body fat, and parameters set such as the currently operating wavelength and output power are transmitted to the mobile software, and thereafter, the cloud It is transmitted to the server and stored, and through big data analysis based on medical-level physiological measurement information, the current state of health and the corresponding health management information, and the setting optimization correction value of the wearing device are transmitted back to the mobile software. It is a personalized smart healthcare platform that allows users to check their own health information and management information, and automatically corrects the optimum setting value of the body fat decomposition wear device when using the body fat decomposition wear device again.

In addition, a service that provides fun and motivation for health care, such as grouping people with similar health status and providing products through data mining in a way that all members of the group achieve a common goal. It is a Health K platform that also incorporates blockchain technology that can provide

Metabolic monitoring-based body fat decomposition wearing device (p) is configured by connecting the above-described metabolic monitoring-based body fat decomposition device (1) to each other, is composed of a number of sections, is configured to be wearable, and wearers in a worn state Metabolic measurement data is generated by monitoring the metabolism of the body, and according to the metabolic measurement data, light is emitted to the odor side of the wearer to decompose body fat.

The terminal 10 is capable of transmitting and receiving data with the wearing device p for decomposing body fat, receiving the metabolic measurement data, and transmitting the wearing device setting and control information. In addition, the terminal 10 transmits the metabolic measurement data to the cloud server 20. Then, personalized data is received from the cloud server 20.

The cloud server 20 receives the metabolic measurement data from the terminal 10, operates a block compensation system using big data analysis and blockchain technology according to the metabolic measurement data, and creates personalized data according to the operation. And transmits it to the terminal 10.

6 is a flowchart illustrating a process of processing mutual data between a wearing device for body fat decomposition based on metabolic monitoring, a mobile app, and a cloud server. The body fat decomposition wearing device (p) and the mobile app first go through a wireless connection process (S100) through Bluetooth, etc., and then perform a process (S110) of applying the setting values of the body fat decomposition wearing device stored in advance in the mobile app. . Here, the set value means a set value for adjusting the light source for body fat decomposition, and is a set value for adjusting the received light source for body fat decomposition according to the analysis result based on big data.

Thereafter, the control unit 500 controls the body composition measurement unit 100 to measure metabolic information, and controls the body fat decomposition optical power control unit 400 to decompose body fat and measure the metabolic information again (S120). After that, the process of transmitting and storing the metabolic measurement data to the mobile app (S130) is performed.

The mobile app transmits and stores the metabolic measurement data stored in the mobile device to the cloud server (S140), and then the cloud server diagnoses the stored database through big data analysis to generate personalized information such as exercise coaching or diet. Then, a process (S150) of changing the light source control setting value for body fat decomposition into a value suitable for the analysis result is performed. The set value for controlling the body fat decomposition light source may be the intensity of the body fat decomposition light for each wavelength, the light irradiation pulse width and total irradiation time as shown in FIG. 4.

Next, the cloud server includes a process of transmitting and storing the changed light source adjustment setting value for body fat decomposition and the big data analysis result data to the mobile app (S160), and then displaying the analysis data on the mobile app (S170). do.

7 is a flowchart illustrating a process of performing block compensation in a cloud server according to an embodiment of the present invention.

Referring to FIG. 7, the individual who does not belong to the block group starts with the process of setting an individual's goal (S200), and whether the set goal has been achieved while performing the steady metabolism measurement, body fat decomposition, and big data analysis process (S210). When the determination is made (S220) and the goal is successfully achieved, a block group is formed with N people with similar health levels, and a common goal is set (S240).

Individuals belonging to each group determine whether they have achieved the set group's common goal (S250) while performing a steady metabolism measurement, body fat decomposition, and big data analysis process (S240). According to the reward, a block group is re-formed with M people with similar health levels, and a common goal is set again (S260). At this time, it is desirable to increase the difficulty of achieving the goal by making the number of people in the block group M more than the number of people in the previous block group, N.

Likewise, in subsequent processes (S270, S280, and S290), compensation and a new block group may be formed and continued according to the achievement of the target.

The contents of the present invention have been described with reference to the embodiments shown in the drawings, but these are only exemplary, and those of ordinary skill in the art will understand that various modifications and other equivalent embodiments are possible therefrom. will be. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1: metabolic monitoring-based body fat decomposition device, 100: body composition measurement unit, 110: body composition measurement light source, 120: light detection unit, 121: first optical sensor, 122: second optical sensor, 123: third optical sensor, 130 : Filtering and amplification unit, 140: optical driver unit, 150: measurement light source switching unit, 160: body composition measurement signal amplification unit, 170: body composition measurement signal switching unit 200: body fat decomposition light source unit, 210: body fat decomposition multi-wavelength light source, 300 : Body fat decomposition signal switching unit, 400: body fat decomposition optical power control unit, 500: control unit, 600: power supply unit, 700: short-range wireless communication unit, 800: connector, p: body fat decomposition wearing device, b: belt

Claims (13)

The body fat decomposition device (1) based on metabolic monitoring is connected to each other, and is composed of a plurality of sections and is configured to be wearable, and the metabolic measurement data that monitors the metabolism of the wearer in the worn state is generated, and the metabolism Metabolic monitoring-based body fat decomposition wearing device (p) for decomposing body fat by emitting light to the wearer's body part according to the measurement data;
A terminal 10 capable of transmitting and receiving data with the wearing device p for decomposing body fat, receiving the metabolic measurement data, and transmitting the wearing device setting and control information;
Including; a server for receiving the metabolic measurement data from the terminal 10, generating personalized data according to the metabolic measurement data, and transmitting it to the terminal 10;
The body fat decomposition device 1,
After irradiating light for measuring the thickness of subcutaneous fat and multi-wavelength body composition to monitor metabolism through the body composition measurement light source unit 110, the diffused light diffused while passing through the internal tissues is transferred to the light detection unit 120. A body composition measuring unit 100 that detects and outputs a thickness and body composition measurement signal of subcutaneous fat;
Body fat decomposition light source 200 for emitting light for decomposing body fat;
Body fat decomposition light power control unit 400 for outputting multi-wavelength light source driving power for outputting the body fat decomposition light of individual body fat decomposition multi-wavelength light sources 210 according to the body fat decomposition light control signal input from the control unit 500;
A body fat decomposition signal switching unit 300 for transmitting power to the multi-wavelength light source driving power output from the body fat decomposition light power control unit 400 to each of the body fat decomposition multi-wavelength light sources 210; And
The body composition measurement light source unit 110 of the body composition measurement unit 100 outputs a body composition measurement light control signal that adjusts the output wavelength and intensity of the body composition measurement light, and the light detection unit 120 of the body composition measurement unit 100 After performing the analysis of the thickness and body composition of the subcutaneous fat using the diffused light signal received by, the metabolism measurement data generated by generating metabolic specific data is controlled to be transmitted to the terminal 10, and the metabolism A control unit 500 for adjusting the intensity and irradiation time of each wavelength of the body fat decomposition light source unit 200 by receiving a set value for adjusting the body fat decomposition light source received according to the result of analysis based on big data according to the measurement data; Including, The body fat decomposition light source adjustment set value is set so that the average light intensity irradiated during the light irradiation period (T) is set to be constant, but is set to increase the output and reduce the pulse width in proportion to the thickness of the analyzed subcutaneous fat. Smart healthcare system for body fat decomposition based on metabolic monitoring. delete The method of claim 1, wherein the metabolic monitoring-based body fat decomposition wearing device (p),
The metabolic monitoring-based body fat decomposition device (1) is connected to each other to be composed of a plurality of sections, the section configuration form is varied according to the body part, and at both ends of the metabolic monitoring-based body fat decomposition wear device (p) A smart healthcare system for metabolic monitoring-based body fat decomposition, which is configured to include a belt (b) that is connected to be worn on a waist or body part. The method of claim 1, wherein an application is installed in the terminal 10, and the application is
An individual's health status installed on a computer or portable device and transmitted from the metabolic monitoring-based body fat decomposition wear device (p) to the server and analyzed by the server based on big data It receives information such as the body fat decomposition light source control setting value, personalized exercise coaching, diet, etc. transmitted according to the computer or portable device, and displays the information of the group connected through the blockchain and the common goals and achievements. A smart healthcare system for body fat decomposition based on metabolic monitoring that is configured to be transmitted and displayed through the server. The method of claim 1, wherein the body composition measuring unit 100,
A body composition measurement light source unit 110 including a multi-wavelength diode array light source chip that outputs body composition measurement lights having respective wavelengths and intensities;
An optical driver unit 140 for outputting a multi-wavelength light source driving power to respective diodes of the multi-wavelength diode array light source chip constituting the body composition measurement light source unit 110;
A measurement light source switching unit 150 for switching the multi-wavelength light source driving power to be input to respective diodes of the multi-wavelength diode array light source chip;
In order to add a modulated signal to the multi-wavelength light source driving power, a modulated signal of a specific frequency is output to the optical driver unit 140, and a body composition measurement signal output through the light detection unit 120 and the body composition measurement signal amplification unit 160 A filtering and amplifying unit 130 outputting the strength of the body composition measurement signal to the control unit 500 after removing noise so as to detect only a signal matching the modulated signal frequency in
The light detection unit 120 including a plurality of optical sensors spaced apart from the body composition measurement light source unit 110 at predetermined intervals to detect the diffused light emitted while passing through the internal tissues of the body and output as the body composition measurement signal ;
A body composition measurement signal amplification unit 160 for amplifying and outputting the body composition measurement signal output from the light detection unit 120; And
Body composition measurement signal switching unit 170 for outputting each of the body composition measurement signals output from the body composition measurement signal amplification unit 160 to the filtering and amplification unit 130; metabolic monitoring-based body fat decomposition comprising Smart healthcare system. The method of claim 1, wherein the metabolic measurement data,
Fat layer thickness for each part of the body, oxygen-bound hemoglobin (HbO2), oxygen-unbound hemoglobin (HbR), body water, Fat %, change in size of fat cells, and the relationship between each measured component and BMI (Body Mass Index) A smart healthcare system for body fat decomposition based on metabolic monitoring that includes one or more of phosphorus R values. The method of claim 1, wherein the body fat decomposition light source unit 200,
Light of 635~680nm wavelength to promote absorption by activating lipolysis, light of 920~930nm wavelength to alleviate cellulite, light of 930~980nm wavelength absorbed a lot from fat and water, 805~830nm to reduce skin aging It includes an array of body fat decomposition multi-wavelength light sources 210 that can be configured to irradiate light of a wavelength by selecting a wavelength or the number of wavelengths according to a function,
The control unit 500 drives a multi-wavelength light source output from the body fat decomposition light power control unit 400 according to the body fat decomposition light control set value generated through big data analysis according to the fat layer thickness and metabolic information for each body part The body fat decomposition light source unit 200 is configured to irradiate light having different intensities and irradiation times according to wavelengths by a power source, a metabolic monitoring-based smart healthcare system for body fat decomposition.
delete delete delete delete delete delete

Images